×
Mpeshe, Saul C.

Fuzzy SEIR epidemic model of amoebiasis infection in human. (English) Zbl 1497.92156

Adv. Fuzzy Syst. 2022, Article ID 5292830, 10 p. (2022).

MSC:

92C60 Medical epidemiology
92D30 Epidemiology
PDF BibTeX XML Cite
\textit{S. C. Mpeshe}, Adv. Fuzzy Syst. 2022, Article ID 5292830, 10 p. (2022; Zbl 1497.92156)
Full Text: DOI

References:

[1] Stanley, S. L., Amoebiasis, The Lancet, 361, 9362, 1025-1034 (2003)
[2] Wilson, I. W.; Weedall, G. D.; Hall, N., Host-Parasite interactions in Entamoeba histolytica and Entamoeba dispar: what have we learned from their genomes, Parasite Immunology, 34, 2, 90-99 (2012)
[3] Choudhuri, G.; Rangan, M., Amebic infection in humans, Indian Journal of Gastroenterology, 31, 4, 153-162 (2012)
[4] Haque, R., Human intestinal parasites, Journal of Health, Population, and Nutrition, 25, 4, 387-391 (2007)
[5] Shirley, D. A. T.; Watanabe, K.; Moonah, S., Significance of amebiasis: 10 reasons why neglecting amebiasis might come back to bite us in the gut, PLoS Neglected Tropical Diseases, 13, 11 (2019)
[6] Lozano, R.; Naghavi, M.; Foreman, K.; Lim, S.; Shibuya, K.; Aboyans, V.; Abraham, J.; Adair, T.; Aggarwal, R.; Ahn, S. Y.; Alvarado, M.; Anderson, H. R.; Anderson, L. M.; Andrews, K. G.; Atkinson, C.; Baddour, L. M.; Barker-Collo, S.; Bartels, D. H.; Bell, M. L.; Benjamin, E. J.; Bennett, D.; Bhalla, K.; Bikbov, B.; Bin Abdulhak, A.; Birbeck, G.; Blyth, F.; Bolliger, I.; Boufous, S.; Bucello, C.; Burch, M.; Burney, P.; Carapetis, J.; Chen, H.; Chou, D.; Chugh, S. S.; Coffeng, L. E.; Colan, S. D.; Colquhoun, S.; Colson, K. E.; Condon, J.; Connor, M. D.; Cooper, L. T.; Corriere, M.; Cortinovis, M.; de Vaccaro, K. C.; Couser, W.; Cowie, B. C.; Criqui, M. H.; Cross, M.; Dabhadkar, K. C.; Dahodwala, N.; De Leo, D.; Degenhardt, L.; Delossantos, A.; Denenberg, J.; Des Jarlais, D. C.; Dharmaratne, S. D.; Dorsey, E. R.; Driscoll, T.; Duber, H.; Ebel, B.; Erwin, P. J.; Espindola, P.; Ezzati, M.; Feigin, V.; Flaxman, A. D.; Forouzanfar, M. H.; Fowkes, F. G.; Franklin, R.; Fransen, M.; Freeman, M. K.; Gabriel, S. E.; Gakidou, E.; Gaspari, F.; Gillum, R. F.; Gonzalez-Medina, D.; Halasa, Y. A.; Haring, D.; Harrison, J. E.; Havmoeller, R.; Hay, R. J.; Hoen, B.; Hotez, P. J.; Hoy, D.; Jacobsen, K. H.; James, S. L.; Jasrasaria, R.; Jayaraman, S.; Johns, N.; Karthikeyan, G.; Kassebaum, N.; Keren, A.; Khoo, J. P.; Knowlton, L. M.; Kobusingye, O.; Koranteng, A.; Krishnamurthi, R.; Lipnick, M.; Lipshultz, S. E.; Ohno, S. L.; Mabweijano, J.; MacIntyre, M. F.; Mallinger, L.; March, L.; Marks, G. B.; Marks, R.; Matsumori, A.; Matzopoulos, R.; Mayosi, B. M.; McAnulty, J. H.; McDermott, M. M.; McGrath, J.; Mensah, G. A.; Merriman, T. R.; Michaud, C.; Miller, M.; Miller, T. R.; Mock, C.; Mocumbi, A. O.; Mokdad, A. A.; Moran, A.; Mulholland, K.; Nair, M. N.; Naldi, L.; Narayan, K. M.; Nasseri, K.; Norman, P.; O’Donnell, M.; Omer, S. B.; Ortblad, K.; Osborne, R.; Ozgediz, D.; Pahari, B.; Pandian, J. D.; Rivero, A. P.; Padilla, R. P.; Perez-Ruiz, F.; Perico, N.; Phillips, D.; Pierce, K.; Pope, C. A.; Porrini, E.; Pourmalek, F.; Raju, M.; Ranganathan, D.; Rehm, J. T.; Rein, D. B.; Remuzzi, G.; Rivara, F. P.; Roberts, T.; De León, F. R.; Rosenfeld, L. C.; Rushton, L.; Sacco, R. L.; Salomon, J. A.; Sampson, U.; Sanman, E.; Schwebel, D. C.; Segui-Gomez, M.; Shepard, D. S.; Singh, D.; Singleton, J.; Sliwa, K.; Smith, E.; Steer, A.; Taylor, J. A.; Thomas, B.; Tleyjeh, I. M.; Towbin, J. A.; Truelsen, T.; Undurraga, E. A.; Venketasubramanian, N.; Vijayakumar, L.; Vos, T.; Wagner, G. R.; Wang, M.; Wang, W.; Watt, K.; Weinstock, M. A.; Weintraub, R.; Wilkinson, J. D.; Woolf, A. D.; Wulf, S.; Yeh, P. H.; Yip, P.; Zabetian, A.; Zheng, Z. J.; Lopez, A. D.; Murray, C. J.; AlMazroa, M. A.; Memish, Z. . A., Global and regional mortality from 235 causes of death for 20 age groups in 1990 and 2010: a systematic analysis for the Global Burden of Disease Study 2010, Lancet, 380, 9859, 2095-2128 (2012)
[7] Ryan, K. J.; Ray, C. G., Sherris Medical Microbiology, 733-738 (2004), New York, USA: McGraw-Hill, New York, USA
[8] Carrero, J. C.; Reyes-López, M.; Serrano-Luna, J.; Shibayama, M.; Unzueta, J.; León-Sicairos, N.; Garza, M. D. L., Intestinal amoebiasis: 160 years of its first detection and still remains as a health problem in developing countries, International journal of medical microbiology : IJMM, 310 (2020)
[9] Pinilla, A. E.; López, M. C.; Viasus, D. F., Historia del protozoo Entamoeba histolytica, Rev. Med. Chile Supl., 136, 118-124 (2008)
[10] Stark, D.; Harkness, J.; Beebe, N.; Fotedar, R.; Marriott, D.; Ellis, J. T.; Van Hal, S., Prevalence of enteric protozoa in human immunodeficiency virus (HIV)-positive and HIV-negative men who have sex with men from Sydney, Australia, The American Journal of Tropical Medicine and Hygiene, 76, 3, 549-552 (2007)
[11] Stark, D.; van Hal, S. J.; Matthews, G.; Harkness, J.; Marriott, D., Invasive amebiasis in men who have sex with men, Australia, Emerging Infectious Diseases, 14, 7, 1141-1143 (2008)
[12] Salit, I. E.; Khairnar, K.; Gough, K.; Pillai, D. R., A possible cluster of sexually TransmittedEntamoeba histolytica:genetic analysis of a highly virulent strain, Clinical Infectious Diseases, 49, 3, 346-353 (2009)
[13] Hung, C. C.; Chang, S. Y.; Ji, D. D., Entamoeba histolytica infection in men who have sex with men, The Lancet Infectious Diseases, 12, 9, 729-736 (2012)
[14] Samie, A.; ElBakri, A.; AbuOdeh, R., Amoebiasis in the tropics: epidemiology and pathogenesis, Current Topics in Tropical Medicine (2012), London, UK: InTech, London, UK
[15] Hotez, P. J.; Kamath, A., Neglected tropical diseases in sub-saharan africa: review of their prevalence, distribution, and disease burden, PLoS Neglected Tropical Diseases, 3, 8, e412 (2009)
[16] Tanyuksel, M.; Petri, W. A., Laboratory diagnosis of amebiasis, Clinical Microbiology Reviews, 16, 4, 713-29 (2003)
[17] Heymann, D. L., Control of Communicable Diseases Manual (2015), Washington DC, USA: American Public Health Association, Washington DC, USA
[18] Ximénez, C.; Morán, P.; Rojas, L.; Valadez, A.; Gómez, A., Reassessment of the epidemiology of amebiasis: state of the art, Infection, Genetics and Evolution, 9, 6, 1023-1032 (2009)
[19] Hategekimana, F.; Saha, S.; Chaturvedi, A., Amoebiasis transmission and life cycle: a continuous state description by virtue of existence and uniqueness, Global Journal of Pure and Applied Mathematics, 12, 1, 375-390 (2016)
[20] Hategekimana, F.; Saha, S.; Chaturvedi, A., Dynamics of amoebiasis transmission: stability and sensitivity analysis, Mathematics, 5, 4 (2017) · Zbl 1394.92123
[21] Zimmermann, H.-J., Fuzzy Set Theory—And Applications (2001), Boston: Kluwer Academic Publishers, Boston
[22] Bates, J. H. T.; Young, M. P., Applying fuzzy logic to medical decision making in the intensive care unit, American Journal of Respiratory and Critical Care Medicine, 167, 7, 948-952 (2003)
[23] Smithson, M.; Verkuilen, J., Fuzzy Set Theory: Applications in the Social Sciences. Series, Quantitative Applications in the Social Sciences (2006), CA, USA: Sage Publications, Inc., CA, USA · Zbl 1153.03317
[24] Abdy, M.; Side, S.; Annas, S.; Nur, W.; Sanusi, W., An SIR epidemic model for COVID-19 spread with fuzzy parameter: the case of Indonesia, Advances in Difference Equations, 105, 2021 (2021)
[25] Li, C.; Huang, J.; Chen, Y.-H.; Zhao, H., A fuzzy susceptible-exposed-infected-recovered model based on the confidence index, International Journal of Fuzzy Systems, 23, 907-917 (2021)
[26] Shi, X.; Li, J.; Huang, A.; Song, S.; Yang, Z., Assessing the outbreak risk of epidemics using fuzzy evidential reasoning, Risk Analysis, 41, 11 (2021)
[27] Stiegelmeier, E. W.; Bressan, G. M., A fuzzy approach in the study of covid-19 pandemic in brazil, Research on Biomedical Engineering, 37, 263-271 (2021)
[28] Shaban, W. M.; Rabie, A. H.; Saleh, A. I.; Abo-Elsoud, M. A., Detecting COVID-19 patients based on fuzzy inference engine and Deep Neural Network, Applied Soft Computing Journal, 99 (2021)
[29] Chowdhury, M. A.; Shah, Q. Z.; Kashem, M. A.; Shahid, A.; Akhtar, N., Evaluation of the effect of environmental parameters on the spread of COVID-19: a fuzzy logic approach, Advances in Fuzzy Systems, 2020 (2020)
[30] Bhuju, G.; Phaijoo, G. R.; Gurung, D. B., Fuzzy approach analyzing SEIR-SEI dengue dynamics, BioMed Research International, 2020 (2020)
[31] Barros, L. C. D.; Bassanezi, R. C.; Leite, M. B. F., The SI epidemiological models with a fuzzy transmission parameter, Computers & Mathematics with Applications, 45, 10, 1619-1628 (2003) · Zbl 1043.92032
[32] Zadeh, L. A., The Concept of a Linguistic Variable and its Application to Approximate Reasoning (1973), Berkeley: Memorandum ERL-M 41l, Berkeley
[33] Barros, L. C.; Oliveira, R. Z. G.; Leite, M. B. F.; Bassanezi, R. C., Epidemiological models of directly transmitted diseases: an approach via fuzzy sets theory, International Journal of Uncertainty, Fuzziness and Knowledge-Based Systems, 22, 5, 769-781 (2014) · Zbl 1323.92198
[34] Verma, R.; Tiwari, S. P.; Upadhyay, R. K.; Kacprzyk, J.; Szmidt, E.; Zadrożny, S.; Atanassov, K.; Krawczak, M., Dynamical behaviors of fuzzy SIR epidemic model, Advances in Fuzzy Logic and Technology 2017. EUSFLAT 2017, IWIFSGN 2017 Advances in Intelligent Systems and Computing, 643, 482-492 (2018), Cham: Springer, Cham
[35] Verma, R.; Tiwari, S. P.; Upadhyay, R. K., Fuzzy modeling for the spread of influenza virus and its possible control, Computational Ecology and Software, 8, 1, 32-45 (2018)
[36] Mpeshe, S. C.; Nyerere, N., Modeling approach to assess the transmission dynamics of Hepatitis B infection in Africa, International Journal of Advances in Applied Mathematics and Mechanics, 6, 3, 51-61 (2019) · Zbl 1467.92220
[37] Margaliot, M.; Langholz, G., Fuzzy Lyapunov-based approach to the design of fuzzy controllers, Fuzzy Sets and Systems, 106, 1, 49-59 (1999) · Zbl 0948.93516
[38] Driessche, P. V. D.; Watmough, J., Reproduction numbers and sub-threshold endemic equilibria for compartmental models of disease transmission, Mathematical Biosciences, 180, 1, 29-48 (2002) · Zbl 1015.92036
[39] Vargas-De-Leon, C., Constructions of lyapunov functions for classic SIS, SIR and SIRS epidemic models with variable population size, Revista Electronica Foro Red Mat, 26, 6, 1-12 (2009)
[40] Davis, C. P.; Balentine, J. R., Amebiasis (Entamoeba histolytica infection) (2019), https://www.medicinenet.com/amebiasis_entamoeba_histolytica_infection/article.htm
[41] Mpeshe, S.; Nyerere, N., A human-animal model of giardiasis infection in contaminated environment, International Journal of Advances in Applied Mathematics and Mechanics, 8, 4, 37-47 (2021) · Zbl 1504.92149
This reference list is based on information provided by the publisher or from digital mathematics libraries. Its items are heuristically matched to zbMATH identifiers and may contain data conversion errors. It attempts to reflect the references listed in the original paper as accurately as possible without claiming the completeness or perfect precision of the matching.